Power distribution system

ABSTRACT

A power distribution system and method may include a first power domain having a first plurality of power rails, a second power domain having a second plurality of power rails, where the first power domain is electrically independent of the second power domain, and a plurality of modules coupled to the first power domain and the second power domain, where each of the plurality of modules is coupled to one of the first plurality of power rails and one of the second plurality of power rails. The system may also include a plurality of mated pairs, where each of the plurality of modules is in only one of the plurality of mated pairs, and where each of the plurality of mated pairs is coupled to two separate of the first and second plurality of power rails.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.11/287,645 filed on Nov. 28, 2005. The disclosure of the aboveapplication is incorporated herein by reference.

BACKGROUND

Although an embedded computer system may include redundant cards suchthat the failure of one card will not cause overall system downtime,power outages can cause an entire chassis or shelf to fail. In the priorart, when one card catastrophically fails, its redundant counterpart isoften on the same set of power rails, which can lead to both cardsfailing. This catastrophic power failure can also lead to other cardsfailing in the embedded computer system.

There is a need, not met in the prior art, to protect redundant pairs ofcards from catastrophic power failure. Accordingly, there is asignificant need for an apparatus and method that overcomes thedeficiencies of the prior art outlined above.

BRIEF DESCRIPTION OF THE DRAWINGS

Representative elements, operational features, applications and/oradvantages of the present disclosure reside inter alia in the details ofconstruction and operation as more fully hereafter depicted, describedand claimed—reference being made to the accompanying drawings forming apart hereof, wherein like numerals refer to like parts throughout. Otherelements, operational features, applications and/or advantages willbecome apparent in light of certain exemplary embodiments recited in theDetailed Description, wherein:

FIG. 1 representatively illustrates an embedded computer chassis inaccordance with an exemplary embodiment;

FIG. 2 representatively illustrates a block diagram of a powerdistribution system in accordance with an exemplary embodiment;

FIG. 3 representatively illustrates a block diagram of a powerdistribution system in accordance with another exemplary embodiment;

FIG. 4 representatively illustrates a block diagram of a powerdistribution system in accordance with yet another exemplary embodiment;

FIG. 5 representatively illustrates a block diagram of a powerdistribution system in accordance with still another exemplaryembodiment;

FIG. 6 representatively illustrates a block diagram of a powerdistribution system in accordance with still yet another exemplaryembodiment; and

FIG. 7 representatively illustrates a flow diagram in accordance with anexemplary embodiment.

Elements in the Figures are illustrated for simplicity and clarity andhave not necessarily been drawn to scale. For example, the dimensions ofsome of the elements in the Figures may be exaggerated relative to otherelements to help improve understanding of various embodiments.Furthermore, the terms “first”, “second”, and the like herein, if any,are used inter alia for distinguishing between similar elements and notnecessarily for describing a sequential or chronological order.Moreover, the terms “front”, “back”, “top”, “bottom”, “over”, “under”,and the like in the Description and/or in the Claims, if any, aregenerally employed for descriptive purposes and not necessarily forcomprehensively describing exclusive relative position. Any of thepreceding terms so used may be interchanged under appropriatecircumstances such that various embodiments described herein may becapable of operation in other configurations and/or orientations thanthose explicitly illustrated or otherwise described.

DETAILED DESCRIPTION

The following representative descriptions generally relate to exemplaryembodiments and the inventor's conception of the best mode, and are notintended to limit the applicability or configuration in any way. Rather,the following description is intended to provide convenientillustrations for implementing various embodiments. As will becomeapparent, changes may be made in the function and/or arrangement of anyof the elements described in the disclosed exemplary embodiments withoutdeparting from the spirit and scope of the disclosure.

Various representative implementations of the present disclosure may beapplied to any system for power distribution. Certain representativeimplementations may include, for example AC power distribution, DC powerdistribution, and power distribution in an embedded computer chassis orsystem of multiple chassis.

For clarity of explanation, the embodiments are presented, in part, ascomprising individual functional blocks. The functions represented bythese blocks may be provided through the use of either shared ordedicated hardware, including, but not limited to, hardware capable ofexecuting software. The present disclosure is not limited toimplementation by any particular set of elements, and the descriptionherein is merely representational of one embodiment.

Software blocks that perform embodiments can be part of computer programmodules comprising computer instructions, such control algorithms thatare stored in a computer-readable medium such as memory. Computerinstructions can instruct processors to perform any methods describedbelow. In other embodiments, additional modules could be provided asneeded.

A detailed description of an exemplary application is provided as aspecific enabling disclosure that may be generalized to any applicationof the disclosed system, device and method for distribution of power inaccordance with various embodiments.

FIG. 1 representatively illustrates an embedded computer chassis inaccordance with an exemplary embodiment. As shown in FIG. 1, embeddedcomputer chassis 100 may include a backplane 103, with software and aplurality of slots 102 for inserting modules, for example, switchmodules 108 and payload modules 110. Backplane 103 may be used forcoupling modules placed in plurality of slots 102 and powerdistribution.

As shown in FIG. 1, embedded computer chassis 100 may comprise at leastone switch module 108 coupled to any number of payload modules 110 viabackplane 103. Backplane 103 may accommodate any combination of a packetswitched backplane including a distributed switched fabric or amulti-drop bus type backplane. Bussed backplanes may include VME,CompactPCI, and the like. Payload modules 110 may add functionality toembedded computer chassis 100 through the addition of processors,memory, storage devices, I/O elements, and the like. In other words,payload module 110 may include any combination of processors, memory,storage devices, I/O elements, and the like, to give embedded computerchassis 100 any functionality desired by a user. In the embodimentshown, there are sixteen slots 102 to accommodate any combination ofswitch modules 108 and payload modules 110. However, an embeddedcomputer chassis 100 with any number of slots may be included in thescope of the disclosure. For example, embedded computer chassis 100 mayinclude fourteen slots 102 and be within the scope of the disclosure.

In an embodiment, embedded computer chassis 100 can use switch module108 as a central switching hub with any number of payload modules 110coupled to switch module 108. Embedded computer chassis 100 may supporta point-to-point, switched input/output (I/O) fabric. Embedded computerchassis 100 may include both node-to-node (for example computer systemsthat support I/O node add-in slots) and chassis-to-chassis environments(for example interconnecting computers, external storage systems,external Local Area Network (LAN) and Wide Area Network (WAN) accessdevices in a data-center environment). Embedded computer chassis 100 maybe implemented by using one or more of a plurality of switched fabricnetwork standards, for example and without limitation, InfiniBand™,Serial RapidIO™, Ethernet™, AdvancedTCA™, PCI Express™ and the like.Embedded computer chassis 100 is not limited to the use of theseswitched fabric network standards and the use of any switched fabricnetwork standard is within the scope of the disclosure.

In one embodiment, backplane 103 can be an embedded packet switchedbackplane as is known in the art. In another embodiment, backplane 103can be an overlay packet switched backplane that is overlaid on top of abackplane that does not have packet switched capability. In anyembodiment, switch module 108 may communicate with payload modules 110via a plurality of links, for example and without limitation, 100-ohmdifferential signaling pairs.

In an embodiment, embedded computer chassis 100 and backplane 103 canuse the CompactPCI (CPCI) Serial Mesh Backplane (CSMB) standard as setforth in PCI Industrial Computer Manufacturers Group (PICMG®)specification 2.20, promulgated by PICMG, 301 Edgewater Place, Suite220, Wakefield, Mass. CSMB provides infrastructure for applications suchas Ethernet, Serial RapidIO, other proprietary or consortium basedtransport protocols, and the like. In another embodiment embeddedcomputer chassis 100 can use an Advanced Telecom and ComputingArchitecture (ATCA™) standard as set forth by PICMG. The embodiment isnot limited to the use of these standards, and the use of otherstandards is within the scope of the disclosure.

Embedded computer chassis 100 can include multiple power domains coupledto provide power, via backplane 103, to switch modules 108 and payloadmodules 110. Power domains can supply for example and withoutlimitation, DC voltage to backplane 103 along any number of power rails,bus bars, or conductors. Switch modules 108 and payload modules 110 maybe coupled to the power rails on the backplane 103. Multiple powerdomains may be independent of each other so as to provide independentand redundant power to backplane 103. In other words, multiple powerdomains may be electrically isolated so as to provide power redundancyto embedded computer chassis 100.

In an embodiment, embedded computer chassis 100 may provide redundancyin the slot configuration by providing that each slot 104 has acorresponding slot 106 such that module 105 in slot 104 has acorresponding module 107 in corresponding slot 106. In an embodiment,module 105 and corresponding module 107 may provide the same function toembedded computer chassis 100 such that module 105 and correspondingmodule 107 are redundant in embedded computer chassis 100. For example,if module 105 were to cease to function, corresponding module 107 mayassume the functions of module 105 without interruption of service. Thisredundancy may hold for both switch modules and payload modules andprovides embedded computer chassis 100 with greater reliability.

In the embodiment shown, slot 1 and slot 2, which may but do not need tocorrespond to a physical adjacency, may contain switch modules 108 suchthat the switch modules perform redundant functions. In this embodiment,slot 1 corresponds to slot 2 and the switch module in slot 1 correspondsto the switch module in slot 2. In another embodiment, slot 13 and slot14, which may but do not need to correspond to a physical adjacency, maycontain payload modules 110 such that the payload modules performredundant functions. In this embodiment, slot 13 corresponds to slot 14and the payload module in slot 13 corresponds to the payload module inslot 14.

In the embodiment depicted in FIG. 1, slot 1 and corresponding slot 2are at opposite ends of embedded computer chassis 100 and may beidentified by their logical implementation. This separation may be toensure maximum separation distance between switch modules 108 forincreased reliability in case of the failure of one switch module. Othermated pairs of slots may be separated by substantially a half-length ofembedded computer chassis 100. For example, logical slot 3 maycorrespond with logical slot 4 such that slot 3 and corresponding slot 4are separated by substantially a half-length of embedded computerchassis 100. In another illustrative example, logical slot 9 maycorrespond with logical slot 10 such that slot 9 and corresponding slot10 are separated by substantially a half-length of embedded computerchassis 100. The slot locations depicted in FIG. 1 are not limiting ofthe disclosure. Other slot configurations that separate slots andcorresponding slots by more or less than a half-length of embeddedcomputer chassis are within the scope of the disclosure.

The number of slots 102 depicted in embedded computer chassis 100 isillustrative and not limiting of the disclosure. The logical andphysical slot designations may be defined by one skilled in the art.Embedded computer chassis 100 may have any number of slots and modulesand be within the scope of the disclosure. Further, although slots andmodules are depicted in a vertical orientation, this is not limiting ofthe disclosure. Embedded computer chassis 100 may have slots and modulesin a horizontal orientation or a combination of horizontal and verticalorientations and be within the scope of the disclosure.

FIG. 2 representatively illustrates a block diagram of a powerdistribution system 200 in accordance with an exemplary embodiment. Inan embodiment, power distribution system 200 may be implemented inembedded computer chassis 100, but this is not limiting of thedisclosure. Power distribution system 200 may be implemented in otherenvironments and be within the scope of the disclosure.

As shown in FIG. 2, power distribution system 200 may include a firstpower domain 202 having a first power entry module 220 and a secondpower domain 204 having a second power entry module 222. First powerdomain 202 may include a first plurality of power rails 206, whilesecond power domain 204 may include a second plurality of power rails208.

First and second power entry modules may function to filter and monitorpower entering embedded computer chassis 100 and distribute power to itsassociated power rails. In an exemplary embodiment, first power entrymodule 220 and second power entry module 222 may function to filter 100amp, −48V DC power and distribute to first plurality of power rails 206and second plurality of power rails 208 respectively. Distribution tofirst plurality of power rails 206 may occur over first set of feedlines 224. Distribution to second plurality of power rails 208 may occurover second set of feed lines 226. In an embodiment, feed lines may besynonymous with power rails.

First power domain 202 and second power domain 204 may be independent ofeach other so as to provide power independently and redundantly to powerdistribution system 200. In other words, first power domain 202 andsecond power domain 204 may be electrically isolated so as to providepower redundancy to power distribution system 200.

In an embodiment, first power domain 202 and second power domain 204 maybe coupled to plurality of modules 210. In an embodiment, plurality ofmodules 210 may be switch modules 108, payload modules 110, and thelike, as discussed with reference to FIG. 1. In an embodiment, pluralityof modules 210 may also belong to plurality of mated pairs 212, whereeach of the plurality of modules 210 is in only one of the plurality ofmated pairs 212. For example, one of plurality of mated pairs 212 mayinclude module 1 and module 2. Another one of plurality of mated pairs212 may include module 3 and module 4, and so on. In the block diagramembodiment a power distribution system 200 shown in FIG. 2, the upperset of plurality of modules (1, 3, 5, . . . ) corresponds to one of thelower set of plurality of power modules (2, 4, 6, . . . ) to formplurality of mated pairs 212. This is not limiting of the disclosure asother schematic combinations of modules may form plurality of matedpairs 212 and be within the scope of the disclosure.

In an embodiment, a module and its corresponding module may provide thesame function to embedded computer chassis such that the module and itscorresponding module are redundant. For example, if module 1 were tocease to function, corresponding module 2 may assume the functions ofmodule 1 without interruption of service. The module designations ofFIG. 2 may be mapped to the slot designations of the system.

In the embodiment shown, each power domain may include two power rails.First power domain 202 may include two power rails (power rail A1 215and power rail A2 216), while second power domain 204 may include twopower rails (power rail B1 217 and power rail B2 218). Each power railmay supply power to one or more of plurality of modules 210. For exampleand not limiting of the disclosure, if 50 amps of current is being fedto each power entry module, then each power rail can supply 25 amps toeach connected module.

In an embodiment, power distribution system 200 is coupled to provide aredundant, reliable source of power to each of the plurality of modules210. To provide this redundancy, each module may be coupled to one powerrail from each of the first power domain 202 and the second power domain204. If one or more of first plurality of power rails 206 in the firstpower domain 202 or one or more of second plurality of power rails 208in the second power domain 204 fail, the module will still be able todraw power from the remaining power domain. For example, module 1 iscoupled to power rail A1 215 from first plurality of power rails 206 infirst power domain 202 and power rail B1 217 from second plurality ofpower rails 208 in second power domain 204.

In some circumstances, failure of one of the plurality of modules maycause one or both of the power rails coupled to that module to fail.This can have the effect of cutting off power supplied to other modulesas well. In some instances, power to both modules in a mated pair can befaulted; thereby causing the functionality of that mated pair to beremoved from the system and potentially causing unacceptable systemdowntime. In order to maximize reliability and minimize the chances forsuch failures to occur, an embodiment of the disclosure interleaves thecoupling of power rails to plurality of modules 210.

In an embodiment, power rails can be interleaved to plurality of slots102 via the backplane 103 in an embedded computer chassis 100 so as toprovide maximum reliability while supplying redundant power to each ofplurality of modules 210 coupled to each of plurality of slots 102.However, this is not limiting of the scope of the disclosure, as powerdistribution system 200 may be applied in other environments and usingother delivery mechanisms besides a backplane and still be within thescope of the disclosure.

In an embodiment, interleaving power rails on each of first power domain202 and second power domain 204 may follow one or more guidelines so asto maximize reliability and minimize the chance that a module-centricfailure will disable other modules in the system.

In an embodiment, one guideline for interleaving power rails is thateach of the plurality of modules is coupled to one of the firstplurality of power rails 206 and one of the second plurality of powerrails 208 such that in a mated pair, each module is coupled to twoseparate of the first and second plurality of power rails. In otherwords, each module in a mated pair 212 is coupled a different set ofpower rails from the two power domains. In an exemplary embodiment, eachof the plurality of modules 210 may be coupled to a 2-tuple of one ofthe first plurality of power rails 206 and one of the second pluralityof power rails 208. This ensures that no two modules from a mated pair212 are coupled to the same set of first plurality of power rails andsecond plurality of power rails.

Table 1 illustrates that the mapping of power rails to modules depictedin FIG. 2 meets the criteria of the guideline above in that allcombinations of 2-tuples of power rails <1,1>, <1,2>, <2,1>, <2,2> areaccounted for in the entries of the table, where PR-A and PR-B refer tofirst plurality of power rails (A1,A2) and second plurality of powerrails (B1,B2) respectively, and LS-A and LS-B refer to the logicalslot/module A (the upper half of plurality of modules) and logicalslot/module B of the mated pair (the lower half of plurality of modules)respectively.

TABLE 1 Mapping of Power Rails to Mated Slots (logical slot orientation)Power Rails LS-A Mated Slots Power Rails LS-B <PR-A, PR-B> <LS-A, LS-B><PR-A, PR-B> <1, 1> <1, 2> <2, 2> <1, 2> <3, 4> <2, 1> <1, 1> <5, 6> <2,2> <1, 2> <7, 8> <2, 1> <1, 1>  <9, 10> <2, 2> <1, 2> <11, 12> <2, 1><1, 1> <13, 14> <2, 2> <1, 2> <15, 16> <2, 1>

FIG. 3 representatively illustrates a block diagram of a powerdistribution system 300 in accordance with another exemplary embodiment.The embodiment, depicted in FIG. 3 represents an analogous powerdistribution system as that depicted in FIG. 2, where like elements havelike numbers. In the embodiment, depicted in FIG. 3, one of theplurality of modules 310 (module 1) is illustrated in a fault conditionsuch as to cause both its power rails to fail as well (the X's and boldlines indicate which module, power rails and connections are failed).

In this embodiment, the failure of module 1 has disabled the two powerrails coupled to module 1, so that other modules coupled to these failedpower rails cannot receive power from the faulted power rails. As shown,one power rail from each of first plurality of power rails 306 andsecond plurality of power rails 308 is disabled. The failure of module 1disables not only module 1, but modules 5, 9 and 13 as well. The dualpower rail failure caused by the failure of module 1 has also causedeight other modules (3, 4, 7, 8, 11, 12, 15 and 16) to go into simplexpower mode where each of these modules is supplied power by only oneactive power rail. The remaining four modules (2, 6, 10 and 14) remainin duplex power mode where each is supplied by two active power rails.

The power failure illustrated in FIG. 3, faults sixteen powerconnections, two on failed module 1, two each on modules 5, 9 and 13,and eight on modules that are now running in simplex (single powersupply) power distribution mode (no redundancy). Also, as shown, thefailure of module 1 does not disable the mated pair 312, as module 2 isstill operational in duplex mode (power redundancy). In sum, theresulting configuration of power distribution system 300 is eightslots/modules running in simplex power distribution mode, fourslots/modules running in duplex power distribution mode and four failedslot/module as a result of the dual power rail failure, where no matedpair is failed.

There are four cases for a first dual power rail failure as describedabove, depending on which of the two power rails in each domain failed.The first case described above is the failure of power rail A1 415 andpower rail B1 417. The second case is the failure of power rail A1 415and power rail B2 418. The third case is the failure of power rail A2416 and power rail B1 417. The fourth case is the failure of power railA2 416 and power rail B2 418. All of these cases have the same effect onthe power distribution system 400.

Given these four cases of a first dual power rail failure, there aresixteen cases for a second dual power rail failure depending on the caseof the first and second dual power rail failure. The combinations ofthese two dual power rail failures fall into patterns of the form<Acase, Bcase>, where Acase and Bcase are either “same” or “diff” andindicate whether the two power rail failures in power domain A 402 areon the same or different power rails and whether the two power railfailures in power domain B 404 are on the same or different power rails.Table 2 illustrates mapping of the sixteen possible combinations to<Acase, Bcase> format. For example, if the first dual power rail failuretakes out power rail A1 415 and power rail B1 417, and the second dualpower rail failure takes out the same two power rails, this would be a<same, same> case as shown in the first row of Table 2.

TABLE 2 Two Dual Power Rail Failures First Failure Second Failure CaseName <PR-A, PR-B> <PR-A, PR-B> <Acase, Bcase> <A1, B1> <A1, B1> <same,same> <A1, B1> <A1, B2> <same, diff> <A1, B1> <A2, B1> <diff, same> <A1,B1> <A2, B2> <diff, diff> <A1, B2> <A1, B1> <same, diff> <A1, B2> <A1,B2> <same, same> <A1, B2> <A2, B1> <diff, diff> <A1, B2> <A2, B2> <diff,same> <A2, B1> <A1, B1> <diff, same> <A2, B1> <A1, B2> <diff, diff> <A2,B1> <A2, B1> <same, same> <A2, B1> <A2, B2> <same, diff> <A2, B2> <A1,B1> <diff, diff> <A2, B2> <A1, B2> <diff, same> <A2, B2> <A2, B1> <same,diff>  <A2, B2>>  <A2, B2>> <same, same>

The following figures and descriptions illustrate exemplary embodimentsof the cases put forth in Table 2 on the effects of a second dual powerrail failure.

FIG. 4 representatively illustrates a block diagram of a powerdistribution system 400 in accordance with yet another exemplaryembodiment. The embodiment, depicted in FIG. 4 represents an analogouspower distribution system as that depicted in FIG. 3, where likeelements have like numbers.

In the embodiment, depicted in FIG. 4, two of the plurality of modules410 (module 1 and module 5) are illustrated in a fault condition such asto cause both of their power rails to fail (the X's and bold linesindicate which module, power rails and connections are failed). Theembodiment of FIG. 4 illustrates the <same, same> case of dual powerrail failure since the failure of both module 1 and module 5 cause powerrail A1 415 and power rail B1 417 to fail.

In this embodiment, the failure of module 1 has disabled the two powerrails coupled to module 1, so that other modules coupled to these failedpower rails cannot receive power from the faulted power rails. Thefailure of module 5 disables the two power rails coupled to module 5, sothat other modules coupled to these failed power rails cannot receivepower. Since module 1 and module 5 are coupled to the same set of powerrails, the second dual power rail failure (module 5) does not cause anypower rail failures past those caused by the failure of module 1. Asshown, one power rail from each of first plurality of power rails 406and second plurality of power rails 408 is disabled. The dual power railfailure of modules 1 and 5 disable not only module 1 and module 5, butmodules 9 and 13 as well. The dual power rail failure caused by thefailure of module 1 and module 5 has also caused eight other modules (3,4, 7, 8, 11, 12, 15 and 16) to go into simplex power mode where each ofthese modules is supplied power by only one active power rail. Theremaining four modules (2, 6, 10 and 14) remain in duplex power modewhere each is supplied by two active power rails.

The power failure illustrated in FIG. 4, faults sixteen powerconnections, two each on failed module 1 and module 5, two each onmodules, 9 and 13, and eight on modules that are now running in simplex(single power supply) power distribution mode (no redundancy). Also, asshown, the failure of module 1 and module 5 does not disable any matedpairs as modules 1, 5, 9 and 13 are failed but their respective mates 2,6, 10 and 14 are still operational in duplex mode (power redundancy). Insum, the resulting configuration of power distribution system 400 iseight slots/modules running in simplex power distribution mode, fourslots/modules running in duplex power distribution mode and four failedslot/module as a result of the dual power rail failure, where no matedpair is failed. It is clear from this exemplary embodiment, that thefailure of two modules and their associated power rails leaves a robustand fully operational power distribution system 400 in place.

FIG. 5 representatively illustrates a block diagram of a powerdistribution system 500 in accordance with still another exemplaryembodiment. The embodiment, depicted in FIG. 5 represents an analogouspower distribution system as that depicted in FIG. 3, where likeelements have like numbers.

In the embodiment, depicted in FIG. 5, two of the plurality of modules510 (module 1 and module 3) are illustrated in a fault condition such asto cause both of their power rails to fail (the X's and bold linesindicate which module, power rails and connections are failed). Theembodiment of FIG. 5 illustrates the <same, diff> case of dual powerrail failure. Both module 1 and module 3 have power rail A1 515 incommon, while module 1 utilizes power rail B1 517 and module 3 utilizespower rail B2 518. So the failure of module 1 and module 3 causes thefailure of power rail A1 515, power rail B1 517 and power rail B2 518.

In this embodiment, the failure of module 1 has disabled the two powerrails coupled to module 1, so that other modules coupled to these failedpower rails cannot receive power from the faulted power rails. Thefailure of module 3 disables the two power rails coupled to module 3, sothat other modules coupled to these failed power rails cannot receivepower. As shown, one power rail from the first plurality of power rails506 and two power rails from second plurality of power rails 508 aredisabled. The dual power rail failure of modules 1 and 3 disable notonly module 1 and module 3, but modules 5, 7, 9, 11, 13 and 15 as well.The dual power rail failure caused by the failure of module 1 and module3 has also caused the remaining eight modules (2, 4, 6, 8, 10, 12, 14and 16) to go into simplex power mode where each of these modules issupplied power by only one active power rail. No modules remain induplex power mode.

The power failure illustrated in FIG. 5, faults twenty four powerconnections, two each on failed module 1 and module 3, two each onmodules, 5, 7, 9, 11, 13 and 15, and eight on modules that are nowrunning in simplex (single power supply) power distribution mode (noredundancy). Also, as shown, the failure of module 1 and module 3 doesnot cause any mated pairs to fail as modules 1, 3, 5, 7, 9, 13 and 15are failed but their respective mates 2, 4, 6, 8, 10, 12, 14 and 16 arestill operational in simplex mode (no power redundancy). In sum, theresulting configuration of power distribution system 500 is two failedmodules, six failed slots/modules as a result of the two dual power railfailures and eight slots/modules running in simplex power distributionmode, where no mated pair is failed. It is clear from this exemplaryembodiment, that the failure of two modules and their associated powerrails leaves a robust and fully operational power distribution system500 in place.

FIG. 6, representatively illustrates a block diagram of a powerdistribution system 600 in accordance with still yet another exemplaryembodiment. The embodiment, depicted in FIG. 6 represents an analogouspower distribution system as that depicted in FIG. 3, where likeelements have like numbers.

In the embodiment, depicted in FIG. 6, two of the plurality of modules610 (module 1 and module 4) are illustrated in a fault condition such asto cause both of their power rails to fail (the X's and bold linesindicate which module, power rails and connections are failed). Theembodiment of FIG. 6 illustrates the <diff, same> case of dual powerrail failure. Module 1 is coupled to power rail A1 615, while module 4is coupled to power rail A2 616. However both module 1 and module 4 havepower rail B1 617 in common. So the failure of module 1 and module 4causes the failure of power rail A1 615, power rail A2 616 and powerrail B1 617.

In this embodiment, the failure of module 1 has disabled the two powerrails coupled to module 1, so that other modules coupled to these failedpower rails cannot receive power from the faulted power rails. Thefailure of module 4 disables the two power rails coupled to module 4, sothat other modules coupled to these failed power rails cannot receivepower. As shown, two power rails from the of first plurality of powerrails 606 and one power rail from second plurality of power rails 608are disabled. The dual power rail failure of modules 1 and 4 disable notonly module 1 and module 4, but modules 5, 8, 9, 12, 13 and 16 as well.The dual power rail failure caused by the failure of module 1 and module4 has also caused the remaining eight modules (2, 3, 6, 7, 10, 11, 14and 15) to go into simplex power mode where each of these modules issupplied power by only one active power rail. No modules remain induplex power mode.

The power failure illustrated in FIG. 6, faults twenty four powerconnections, two each on failed module 1 and module 4, two each onmodules, 5, 8, 9, 12, 13 and 16, and eight on modules that are nowrunning in simplex (single power supply) power distribution mode (noredundancy). Also, as shown, the failure of module 1 and module 4 doesnot cause any mated pairs to fail as modules 1, 4, 5, 8, 9, 12, 13 and16 are failed but their respective mates 2, 3, 6, 7, 10, 11, 14 and 15are still operational in simplex mode (no power redundancy). In sum, theresulting configuration of power distribution system 600 is two failedmodules, six failed slots/modules as a result of the two dual power railfailures and eight slots/modules running in simplex power distributionmode, where no mated pair is failed. It is clear from this exemplaryembodiment, that the failure of two modules and their associated powerrails leaves a robust and fully operational power distribution system500 in place.

Although not shown or discussed, the <diff, diff> case disables all fourpower rails and consequently disables all slots/modules as well. Sinceall power and all slots/modules are disabled in this case, no discussionis warranted.

The above exemplary embodiments illustrate the robustness of theinterleaved power distribution system depicted in FIGS. 2-6. FIG. 3depicts a power distribution system with slots supplied in both simplexand duplex modes after the first dual rail power fault. FIGS. 4-6 depicta power distribution system with slots supplied in simplex mode aftertwo dual rail power faults.

Table 3 summarizes the results of the two dual power rail failure cases.The expected case and the weighted probability of occurrence show thatnine blades fail, five blades enter simplex power mode, one bladeremains in duplex power mode, and two mated pairs of blades fail. In 75%of the two dual power rail failures, no mated pairs are lots, andtherefore, no service-providing capacity of the chassis is lost. Thisindicates an extremely robust power distribution system in the unlikelyevent of two dual power rail failures.

TABLE 3 Summary of Two Dual Power Rail Failures Number of Number ofNumber of Blades in Blades in Number of Case Name Probability BladesFail Simplex Power Duplex Power Mated Pairs Fail <same, same> 0.25 4 4 40 <same, diff> 0.25 8 8 0 0 <diff, same> 0.25 8 8 0 0 <diff, diff> 0.2516 0 0 8 Expected Case 9 5 1 2

FIG. 7 representatively illustrates a flow diagram 700 in accordancewith an exemplary embodiment. Step 702, provides a first plurality ofpower rails residing substantially in the backplane. In an embodiment,the backplane may reside in an embedded computer chassis. Step 704provides a second plurality of power rails residing substantially in thebackplane, where the first plurality of power rails is electricallyindependent of the second plurality of power rails.

Step 706 provides a plurality of slots coupled to one of the firstplurality of power rails and one of the second plurality of power rails,while step 708 provides a plurality of mated pairs, where each of theplurality of slots is in only one of the plurality of mated pairs. Instep 710, each of the plurality of mated pairs is coupled to twoseparate of the first and second plurality of power rails.

In the foregoing specification, the disclosure has been described withreference to specific exemplary embodiments; however, it will beappreciated that various modifications and changes may be made withoutdeparting from the scope of the present disclosure as set forth in theclaims below. The specification and figures are to be regarded in anillustrative manner, rather than a restrictive one and all suchmodifications are intended to be included within the scope of thepresent disclosure. Accordingly, the scope of the disclosure should bedetermined by the claims appended hereto and their legal equivalentsrather than by merely the examples described above.

For example, the steps recited in any method or process claims may beexecuted in any order and are not limited to the specific orderpresented in the claims. Additionally, the components and/or elementsrecited in any apparatus claims may be assembled or otherwiseoperationally configured in a variety of permutations to producesubstantially the same result as the present disclosure and areaccordingly not limited to the specific configuration recited in theclaims.

Benefits, other advantages and solutions to problems have been describedabove with regard to particular embodiments; however, any benefit,advantage, solution to problem or any element that may cause anyparticular benefit, advantage or solution to occur or to become morepronounced are not to be construed as critical, required or essentialfeatures or components of any or all the claims.

As used herein, the terms “comprise”, “comprises”, “comprising”,“having”, “including”, “includes” or any variation thereof, are intendedto reference a non-exclusive inclusion, such that a process, method,article, composition or apparatus that comprises a list of elements doesnot include only those elements recited, but may also include otherelements not expressly listed or inherent to such process, method,article, composition or apparatus. Other combinations and/ormodifications of the above-described structures, arrangements,applications, proportions, elements, materials or components used in thepractice of the present disclosure, in addition to those notspecifically recited, may be varied or otherwise particularly adapted tospecific environments, manufacturing specifications, design parametersor other operating requirements without departing from the generalprinciples of the same.

1. A power distribution system, comprising: a first power domain havinga first plurality of power rails; a second power domain having a secondplurality of power rails, wherein the first power domain is electricallyindependent of the second power domain; a plurality of modules coupledto the first power domain and the second power domain, wherein each ofthe plurality of modules is coupled to one of the first plurality ofpower rails and one of the second plurality of power rails; and aplurality of mated pairs, wherein each of the plurality of modules is inonly one of the plurality of mated pairs, wherein each of the pluralityof mated pairs is coupled to two separate of the first and secondplurality of power rails.
 2. The power distribution system of claim 1,wherein a module in a mated pair is operationally redundant with acorresponding module in the mated pair.
 3. The power distribution systemof claim 2, wherein the module and the corresponding module are at leastone of a payload module and a switch module.
 4. The power distributionsystem of claim 1, wherein the plurality of modules are one of ATCA andCPCI modules.
 5. The power distribution system of claim 1, wherein thefirst and second plurality of power rails reside substantially in abackplane.
 6. The power distribution system of claim 1, wherein thefirst and second plurality of power rails have a DC voltage.
 7. Anembedded computer chassis having a backplane, the embedded computerchassis comprising: a first plurality of power rails residingsubstantially in the backplane; a second plurality of power railsresiding substantially in the backplane, wherein the first plurality ofpower rails is electrically independent of the second plurality of powerrails; a plurality of slots coupled to one of the first plurality ofpower rails and one of the second plurality of power rails; and aplurality of mated pairs, wherein each of the plurality of slots is inonly one of the plurality of mated pairs, wherein each of the pluralityof mated pairs is coupled to two separate of the first and secondplurality of power rails.
 8. The embedded computer chassis of claim 7,wherein each of the plurality of slots is coupled to receive a module.9. The embedded computer chassis of claim 7, wherein each of theplurality of slots in a mated pair is coupled to receive a module whichis operationally redundant with a corresponding module coupled to themated pair.
 10. The embedded computer chassis of claim 9, wherein themodule and the corresponding module are at least one of a payload moduleand a switch module.
 11. The embedded computer chassis of claim 7,wherein the embedded computer chassis is one of an ATCA and CPCIembedded computer chassis.
 12. The embedded computer chassis of claim 7,wherein the first and second plurality of power rails have a DC voltage.13. A method of distributing power in an embedded computer chassis,comprising: providing a first plurality of power rails residingsubstantially in a backplane; providing a second plurality of powerrails residing substantially in the backplane, wherein the firstplurality of power rails is electrically independent of the secondplurality of power rails; providing a plurality of slots coupled to oneof the first plurality of power rails and one of the second plurality ofpower rails; providing a plurality of mated pairs, wherein each of theplurality of slots is in only one of the plurality of mated pairs; andcoupling each of the plurality of mated pairs to two separate of thefirst and second plurality of power rails.
 14. The method of claim 13,wherein each of the plurality of slots is coupled to receive a module.15. The method of claim 13, further comprising coupling each of theplurality of slots in a mated pair to receive a module which isoperationally redundant with a corresponding module coupled to the matedpair.
 16. The method of claim 15, wherein the module and thecorresponding module are at least one of a payload module and a switchmodule.
 17. The method of claim 13, wherein the embedded computerchassis is one of an ATCA and CPCI embedded computer chassis.
 18. Themethod of claim 13, further comprising the first and second plurality ofpower rails having a DC voltage.